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Effects of a 2-year exercise training on neuromuscular system health in older individuals with low muscle function.
Monti, E, Tagliaferri, S, Zampieri, S, Sarto, F, Sirago, G, Franchi, MV, Ticinesi, A, Longobucco, Y, Adorni, E, Lauretani, F, et al
Journal of cachexia, sarcopenia and muscle. 2023;14(2):794-804
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Ageing is accompanied by a progressive decline in muscle mass and functionality, associated with an increased likelihood of adverse outcomes including falls, fractures, physical disability and mortality, possibly leading to a clinical syndrome known as sarcopenia. Among the causes of sarcopenia, motoneuron and neuromuscular junction (NMJ) degeneration have been proposed as key determinants. The aim of this study was to investigate the effects of a 2-year multimodal training intervention involving aerobic, strength and balance exercises on muscle mass and function, motoneuronal and NMJ health in a population of older individuals classified as sarcopenic. This study was a randomised controlled trial which enrolled 45 sarcopenic participants (34 females and 11 males) who were randomly assigned to one of the two groups: intervention or control group. Results show that the 2-year multimodal training intervention seemingly preserved NMJ stability, preventing serum C-terminal agrin fragment (CAF) [a biomarker of muscle wasting and weakness] concentration rise in the intervention group, although this biomarker increased significantly only in the control group. Conversely, neurofilament light chain (NfL) [clinical biomarker of many neurodegenerative diseases] concentration did not change in either group. Finally, improvements of physical performance were correlated with changes of serum biomarkers of NMJ stability. Authors conclude that a 2-year multimodal training intervention including aerobic, strength and balance exercises is effective for preventing CAF concentration increments, suggesting a positive effect on NMJ stability.
Abstract
BACKGROUND Ageing is accompanied by a progressive loss of skeletal muscle mass and strength, potentially determining the insurgence of sarcopenia. Evidence suggests that motoneuron and neuromuscular junction (NMJ) degeneration contribute to sarcopenia pathogenesis. Seeking for strategies able to slow down sarcopenia insurgence and progression, we investigated whether a 2-year mixed-model training involving aerobic, strength and balance exercises would be effective for improving or preserving motoneuronal health and NMJ stability, together with muscle mass, strength and functionality in an old, sarcopenic population. METHODS Forty-five sarcopenic elderly (34 females; 11 males) with low dual-energy X-ray absorptiometry (DXA) lean mass and Short Physical Performance Battery (SPPB) score <9 were randomly assigned to either a control group [Healthy Aging Lifestyle Education (HALE), n = 21] or an intervention group [MultiComponent Intervention (MCI), n = 24]. MCI trained three times per week for 2 years with a mix of aerobic, strength and balance exercises matched with nutritional advice. Before and after the intervention, ultrasound scans of the vastus lateralis (VL), SPPB and a blood sample were obtained. VL architecture [pennation angle (PA) and fascicle length (Lf)] and cross-sectional area (CSA) were measured. As biomarkers of neuronal health and NMJ stability status, neurofilament light chain (NfL) and C-terminal agrin fragment (CAF) concentrations were measured in serum. Differences in ultrasound parameters, NfL and CAF concentration and physical performance between baseline and follow-up were tested with mixed ANOVA or Wilcoxon test. The relationship between changes in physical performance and NfL or CAF concentration was assessed through correlation analyses. RESULTS At follow-up, MCI showed preserved VL architecture (PA, Lf) despite a reduced CSA (-8.4%, P < 0.001), accompanied by maintained CAF concentration and ameliorated overall SPPB performance (P = 0.007). Conversely, HALE showed 12.7% decrease in muscle CSA (P < 0.001), together with 5.1% and 5.5% reduction in PA and Lf (P < 0.001 and P = 0.001, respectively), and a 6.2% increase in CAF (P = 0.009) but improved SPPB balance score (P = 0.007). NfL concentration did not change in either group. In the population, negative correlations between changes in CAF concentration and SPPB total score were found (P = 0.047), whereas no correlation between NfL and SPPB variations was observed. CONCLUSIONS The present findings suggest that our 2-year mixed aerobic, strength and balance training seemed effective for preventing the age and sarcopenia-related increases in CAF concentration, preserving NMJ stability as well as muscle structure (PA and Lf) and improving physical performance in sarcopenic older individuals.
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The effect of weight loss following 18 months of lifestyle intervention on brain age assessed with resting-state functional connectivity.
Levakov, G, Kaplan, A, Yaskolka Meir, A, Rinott, E, Tsaban, G, Zelicha, H, Blüher, M, Ceglarek, U, Stumvoll, M, Shelef, I, et al
eLife. 2023;12
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Obesity is linked to premature brain ageing and subsequent development of diseases such as dementia and Alzheimer’s disease. Weight loss through lifestyle modifications may be able to attenuate brain ageing. This sub-study of 102 individuals from a randomised control trial known as the Dietary Intervention Randomised Controlled Trial Polyphenols Unprocessed Study (DIRECT-PLUS), aimed to determine the effect of 18 months lifestyle modifications and weight loss on brain age. The results showed that a decrease in BMI attenuated brain ageing and that 1% body weight loss reduced brain ageing by 8.9 months. Reduced brain age was also associated with decreased waist circumference and fat mass. Interestingly, reduced consumption of processed foods was also associated with reduced brain age. It was concluded that weight loss can be of benefit to brain health. This study could be used by healthcare professionals to understand that people with obesity are at a higher risk of brain related diseases, and that weight loss may be an effective way to prevent their development.
Abstract
BACKGROUND Obesity negatively impacts multiple bodily systems, including the central nervous system. Retrospective studies that estimated chronological age from neuroimaging have found accelerated brain aging in obesity, but it is unclear how this estimation would be affected by weight loss following a lifestyle intervention. METHODS In a sub-study of 102 participants of the Dietary Intervention Randomized Controlled Trial Polyphenols Unprocessed Study (DIRECT-PLUS) trial, we tested the effect of weight loss following 18 months of lifestyle intervention on predicted brain age based on magnetic resonance imaging (MRI)-assessed resting-state functional connectivity (RSFC). We further examined how dynamics in multiple health factors, including anthropometric measurements, blood biomarkers, and fat deposition, can account for changes in brain age. RESULTS To establish our method, we first demonstrated that our model could successfully predict chronological age from RSFC in three cohorts (n=291;358;102). We then found that among the DIRECT-PLUS participants, 1% of body weight loss resulted in an 8.9 months' attenuation of brain age. Attenuation of brain age was significantly associated with improved liver biomarkers, decreased liver fat, and visceral and deep subcutaneous adipose tissues after 18 months of intervention. Finally, we showed that lower consumption of processed food, sweets and beverages were associated with attenuated brain age. CONCLUSIONS Successful weight loss following lifestyle intervention might have a beneficial effect on the trajectory of brain aging. FUNDING The German Research Foundation (DFG), German Research Foundation - project number 209933838 - SFB 1052; B11, Israel Ministry of Health grant 87472511 (to I Shai); Israel Ministry of Science and Technology grant 3-13604 (to I Shai); and the California Walnuts Commission 09933838 SFB 105 (to I Shai). Obesity is linked with the brain aging faster than would normally be expected. Researchers are able to capture this process by calculating a person’s ‘brain age’ – how old their brain appears on detailed scans, regardless of chronological age. This approach also helps to monitor how certain factors, such as lifestyle, can influence brain aging over relatively short time scales. It is not clear whether lifestyle interventions that promote weight loss can help to slow obesity-driven brain aging. To answer this question, Levakov et al. studied 102 individuals who met the criteria for obesity and took part in a lifestyle intervention aimed to improve diet and physical activity levels over 18 months. The participants received a brain scan at the beginning and the end of the program; additional tests and measurements were also conducted at these times to capture other biological processes impacted by obesity, such as liver health. Levakov et al. used the brain scans taken at the start and end of the study to examine the impact of the lifestyle intervention on the aging trajectory. The results revealed that a reduction in body weight of 1% led to the participants’ brain age being nearly 9 months younger than the expected brain age after 18 months. This attenuated aging was associated with changes in other biological measures, such as decreased liver fat and liver enzymes. Increases in liver fat and production of specific liver enzymes were previously shown to negatively impact brain health in Alzheimer’s disease. Finally, examining more closely the food consumption reports completed by participants showed that reduced consumption of processed food, sweets and beverages were linked to attenuated brain aging. The findings show that lifestyle interventions which promote weight loss can have a beneficial impact on the aging trajectory of the brain observed with obesity. The next steps will include determining whether slowing down obesity-driven brain aging results in better clinical outcomes for patients. In addition, the work by Levakov et al. demonstrates a potential strategy to evaluate the success of lifestyle changes on brain health. With global rates of obesity rising, identifying interventions that have a positive impact on brain health could have important clinical, educational and social impacts.
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Yoga as a Preventive Intervention for Cardiovascular Diseases and Associated Comorbidities: Open-Label Single Arm Study.
Sharma, K, Basu-Ray, I, Sayal, N, Vora, A, Bammidi, S, Tyagi, R, Modgil, S, Bali, P, Kaur, P, Goyal, AK, et al
Frontiers in public health. 2022;10:843134
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Cardiovascular disease, a leading cause of mortality, is on the rise. Inactivity and poor dietary habits can contribute to fat accumulation, increasing cardiovascular disease risk. Yoga is a cost-effective physical activity that may reduce lipid levels. In addition, the practice of yoga may help manage stress, another contributing factor. In this open-label study, AYUSH yoga for 30 days for one hour per day was assessed to improve dyslipidaemia among healthy, comorbid, and trainer participants. The healthy-naive group's cholesterol profile improved significantly compared to the diseased group. Experienced trainers' lipid profiles differed significantly from those of yoga-naive volunteers. Low-density lipoprotein (LDL), total cholesterol (TC), and high-density lipoprotein (HDL) levels were significantly lower than baseline. A significant decrease in systolic blood pressure, pulse rate, and BMI was observed among yoga-naive and healthy participants. In addition, the trainer group had significantly lower LDL and TC/HDL ratios and higher HDL levels. Compared to the comorbid yoga group, the healthy yoga group showed significant differences in physiological parameters such as systolic blood pressure, diastolic blood pressure, and weight after a month of practice, demonstrating that yoga was more effective in healthy participants. These results can help healthcare professionals understand yoga's preventative effects on cardiovascular disease. However, as the current evidence is limited, more robust studies are needed.
Abstract
Aim: Common Yoga Protocol (CYP) is a standardized yoga protocol authored by experts from all over the world under the aegis of the Ministry of AYUSH, Ayurveda, Yoga and Naturopathy, Unani, Siddha, Sowa Rigpa and Homeopathy (AYUSH). The potential of CYP can be determined as a cost-effective lifestyle modification to prevent the risk of developing cardiovascular diseases (CVD). Methods: In this prospective trial, we compared the effect of CYP at baseline and after 1 month. A total of 374 yoga-naïve participants performed CYP under the supervision of experienced trainers. Physiological [body mass index (BMI), blood pressure, percent oxygen saturation], biochemical (fasting blood glucose and lipid profile), and neurocognitive parameters were measured before and after the intervention. Results: At day 30 of yoga practice, serum levels of low-density lipoprotein (LDL), total cholesterol (TC), and high-density lipoprotein (HDL) were found significantly improved as compared to the baseline levels observed at the time of enrollment. Similarly, the lipid profile was also obtained from experienced trainers and found to be significantly different from those of yoga-naïve volunteers. When the intervention was compared between the healthy yoga-naïve participants with yoga-naïve participants suffering from medical issues, it was found that cholesterol profile improved significantly in the healthy-naive group as compared to the diseased group (hypertension, diabetes, underwent surgery, and CVD). Conclusion: These results highlight the need for further research to better understand the effects of yoga on the primary prevention of CVD.
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Precision Medicine Approach to Alzheimer's Disease: Successful Pilot Project.
Toups, K, Hathaway, A, Gordon, D, Chung, H, Raji, C, Boyd, A, Hill, BD, Hausman-Cohen, S, Attarha, M, Chwa, WJ, et al
Journal of Alzheimer's disease : JAD. 2022;88(4):1411-1421
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Neurodegenerative diseases such as Alzheimer’s disease are without effective therapeutics. The aim of this study was to compare the effects of a precision medicine approach to historical controls in patients with mild cognitive impairment or early dementia. This study is a proof-of-concept study which recruited twenty-five patients with Alzheimer’s disease or mild cognitive impairment, aged between 50–76 years. Patients were treated for nine months with a personalised, precision medicine protocol that addressed each patient’s identified potentially contributory factors. Results show that a precision medicine approach to the cognitive decline of Alzheimer’s disease and mild cognitive impairment may be an effective strategy, especially with continued optimization over time. Authors conclude that their findings indicate that it is possible to reverse cognitive decline in mild cognitive impairment and early dementia with a personalised, precision medicine (/systems medicine) protocol. This is a small study that requires larger scale initiatives, including examining the practicalities of integrating this approach into healthcare systems.
Abstract
BACKGROUND Effective therapeutics for Alzheimer's disease are needed. However, previous clinical trials have pre-determined a single treatment modality, such as a drug candidate or therapeutic procedure, which may be unrelated to the primary drivers of the neurodegenerative process. Therefore, increasing data set size to include the potential contributors to cognitive decline for each patient, and addressing the identified potential contributors, may represent a more effective strategy. OBJECTIVE To determine whether a precision medicine approach to Alzheimer's disease and mild cognitive impairment is effective enough in a proof-of-concept trial to warrant a larger, randomized, controlled clinical trial. METHODS Twenty-five patients with dementia or mild cognitive impairment, with Montreal Cognitive Assessment (MoCA) scores of 19 or higher, were evaluated for markers of inflammation, chronic infection, dysbiosis, insulin resistance, protein glycation, vascular disease, nocturnal hypoxemia, hormone insufficiency or dysregulation, nutrient deficiency, toxin or toxicant exposure, and other biochemical parameters associated with cognitive decline. Brain magnetic resonance imaging with volumetrics was performed at baseline and study conclusion. Patients were treated for nine months with a personalized, precision medicine protocol, and cognition was assessed at t = 0, 3, 6, and 9 months. RESULTS All outcome measures revealed improvement: statistically significant improvement in MoCA scores, CNS Vital Signs Neurocognitive Index, and Alzheimer's Questionnaire Change score were documented. No serious adverse events were recorded. MRI volumetrics also improved. CONCLUSION Based on the cognitive improvements observed in this study, a larger, randomized, controlled trial of the precision medicine therapeutic approach described herein is warranted.
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Ketone ester supplementation blunts overreaching symptoms during endurance training overload.
Poffé, C, Ramaekers, M, Van Thienen, R, Hespel, P
The Journal of physiology. 2019;597(12):3009-3027
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Overload training is often used by endurance athletes to improve endurance performance. Overload training, however, can result in muscle protein breakdown, a catabolic state, and a decrease in muscle performance. Therefore, this randomised, double-blinded, placebo-controlled study examined the protective effects of ketone ester supplementation in reducing the detrimental effects of endurance training-induced overreaching. When compared to the control group, the subjects taking oral ketone ester supplements showed a 15% increase in sustained training load and power output and maintained energy balance. Supplementation with ketones ester inhibited the night-time increase in neurotransmitter noradrenaline and hormone adrenaline and maintained heart rate, suggesting a blunting of cardiovascular, sympathetic and hormonal symptoms caused by the endurance training overload. Growth differentiation factor 15 (GDF15) increased by training overload was negated by ketone ester intake. Further studies should be conducted to establish the long-term effects of ketone esters in training and recovery. These results can help healthcare professionals better understand how elevated blood ketones can enhance exercise performance and reduce the detrimental effects of exercise overload.
Abstract
KEY POINTS Overload training is required for sustained performance gain in athletes (functional overreaching). However, excess overload may result in a catabolic state which causes performance decrements for weeks (non-functional overreaching) up to months (overtraining). Blood ketone bodies can attenuate training- or fasting-induced catabolic events. Therefore, we investigated whether increasing blood ketone levels by oral ketone ester (KE) intake can protect against endurance training-induced overreaching. We show for the first time that KE intake following exercise markedly blunts the development of physiological symptoms indicating overreaching, and at the same time significantly enhances endurance exercise performance. We provide preliminary data to indicate that growth differentiation factor 15 (GDF15) may be a relevant hormonal marker to diagnose the development of overtraining. Collectively, our data indicate that ketone ester intake is a potent nutritional strategy to prevent the development of non-functional overreaching and to stimulate endurance exercise performance. ABSTRACT It is well known that elevated blood ketones attenuate net muscle protein breakdown, as well as negate catabolic events, during energy deficit. Therefore, we hypothesized that oral ketones can blunt endurance training-induced overreaching. Fit male subjects participated in two daily training sessions (3 weeks, 6 days/week) while receiving either a ketone ester (KE, n = 9) or a control drink (CON, n = 9) following each session. Sustainable training load in week 3 as well as power output in the final 30 min of a 2-h standardized endurance session were 15% higher in KE than in CON (both P < 0.05). KE inhibited the training-induced increase in nocturnal adrenaline (P < 0.01) and noradrenaline (P < 0.01) excretion, as well as blunted the decrease in resting (CON: -6 ± 2 bpm; KE: +2 ± 3 bpm, P < 0.05), submaximal (CON: -15 ± 3 bpm; KE: -7 ± 2 bpm, P < 0.05) and maximal (CON: -17 ± 2 bpm; KE: -10 ± 2 bpm, P < 0.01) heart rate. Energy balance during the training period spontaneously turned negative in CON (-2135 kJ/day), but not in KE (+198 kJ/day). The training consistently increased growth differentiation factor 15 (GDF15), but ∼2-fold more in CON than in KE (P < 0.05). In addition, delta GDF15 correlated with the training-induced drop in maximal heart rate (r = 0.60, P < 0.001) and decrease in osteocalcin (r = 0.61, P < 0.01). Other measurements such as blood ACTH, cortisol, IL-6, leptin, ghrelin and lymphocyte count, and muscle glycogen content did not differentiate KE from CON. In conclusion, KE during strenuous endurance training attenuates the development of overreaching. We also identify GDF15 as a possible marker of overtraining.
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Metabolic stress-dependent regulation of the mitochondrial biogenic molecular response to high-intensity exercise in human skeletal muscle.
Fiorenza, M, Gunnarsson, TP, Hostrup, M, Iaia, FM, Schena, F, Pilegaard, H, Bangsbo, J
The Journal of physiology. 2018;596(14):2823-2840
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Endurance exercise stimulates mitochondrial biogenesis in skeletal muscles, a crucial adaptive protective mechanism against various metabolic disorders. Mitochondrial biogenesis is a process that involves the expansion of mitochondrial volume and changes in mitochondrial composition. Continuous moderate‐intensity exercise (CM) may lead to mild but prolonged metabolic disturbances, and low‐volume intense intermittent exercise regimes such as repeated‐sprint (RE) and speed endurance (SE) exercises may lead to a distinct degree of metabolic stress. This randomised counter-balanced crossover trial included 12 healthy trained men to investigate the effect of RE and SE exercise and high‐volume CM on metabolic perturbations and its impact on the regulation of molecular response stimulating mitochondrial biogenesis in human skeletal muscle. Compared to CM, PGC‐1α mRNA (Peroxisome proliferator‐activated receptor gamma coactivator 1‐alpha (PGC‐1α) mRNA) showed elevation in response to RS and SE exercises in well-trained subjects, and this was associated with high accumulation of muscle lactate, greater decline in muscle pH and elevated plasma adrenaline levels. Elevated metabolic perturbations lead to enhanced mitochondrial biogenesis-related mRNA responses. SE was associated with a greater increase in the PGC‐1α mRNA and severe metabolic stress. SE and CM elevated exercise-induced signalling and mRNA content of genes controlling mtDNA. Further robust research is required to elucidate the role of metabolic stress in initiating mitochondrial biogenesis in skeletal muscles in response to acute exercise, regulating genes modulating mtDNA transcription and mitochondrial remodelling dynamics. However, healthcare professionals can use the results of this study to understand that low-volume high-intensity exercise programmes can promote mitochondrial biogenesis in skeletal muscles in healthy trained men and have a similar effect to that of high-volume moderate-intensity exercise programmes.
Abstract
KEY POINTS Low-volume high-intensity exercise training promotes muscle mitochondrial adaptations that resemble those associated with high-volume moderate-intensity exercise training. These training-induced mitochondrial adaptations stem from the cumulative effects of transient transcriptional responses to each acute exercise bout. However, whether metabolic stress is a key mediator of the acute molecular responses to high-intensity exercise is still incompletely understood. Here we show that, by comparing different work-matched low-volume high-intensity exercise protocols, more marked metabolic perturbations were associated with enhanced mitochondrial biogenesis-related muscle mRNA responses. Furthermore, when compared with high-volume moderate-intensity exercise, only the low-volume high-intensity exercise eliciting severe metabolic stress compensated for reduced exercise volume in the induction of mitochondrial biogenic mRNA responses. The present results, besides improving our understanding of the mechanisms mediating exercise-induced mitochondrial biogenesis, may have implications for applied and clinical research that adopts exercise as a means to increase muscle mitochondrial content and function in healthy or diseased individuals. ABSTRACT The aim of the present study was to examine the impact of exercise-induced metabolic stress on regulation of the molecular responses promoting skeletal muscle mitochondrial biogenesis. Twelve endurance-trained men performed three cycling exercise protocols characterized by different metabolic profiles in a randomized, counter-balanced order. Specifically, two work-matched low-volume supramaximal-intensity intermittent regimes, consisting of repeated-sprint (RS) and speed endurance (SE) exercise, were employed and compared with a high-volume continuous moderate-intensity exercise (CM) protocol. Vastus lateralis muscle samples were obtained before, immediately after, and 3 h after exercise. SE produced the most marked metabolic perturbations as evidenced by the greatest changes in muscle lactate and pH, concomitantly with higher post-exercise plasma adrenaline levels in comparison with RS and CM. Exercise-induced phosphorylation of CaMKII and p38 MAPK was greater in SE than in RS and CM. The exercise-induced PGC-1α mRNA response was higher in SE and CM than in RS, with no difference between SE and CM. Muscle NRF-2, TFAM, MFN2, DRP1 and SOD2 mRNA content was elevated to the same extent by SE and CM, while RS had no effect on these mRNAs. The exercise-induced HSP72 mRNA response was larger in SE than in RS and CM. Thus, the present results suggest that, for a given exercise volume, the initial events associated with mitochondrial biogenesis are modulated by metabolic stress. In addition, high-intensity exercise seems to compensate for reduced exercise volume in the induction of mitochondrial biogenic molecular responses only when the intense exercise elicits marked metabolic perturbations.
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Effects of a home-based intervention on diet and physical activity behaviours for rural adults with or at risk of metabolic syndrome: a randomised controlled trial.
Blackford, K, Jancey, J, Lee, AH, James, A, Howat, P, Waddell, T
The international journal of behavioral nutrition and physical activity. 2016;13:13
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Metabolic syndrome is characterised by a cluster of symptoms ranging from central obesity to raised triglycerides in the blood. There are thought to be a number of possible risk factors including sedentary lifestyle, a lack of fruit and vegetable consumption and being overweight or obese. This study aimed to determine if a home based lifestyle intervention using motivational interviewing, self-monitoring and goal setting could improve the activity levels and eating behaviours of people aged 50-69, at risk of or with metabolic syndrome in rural disadvantaged Australia. This was a randomised controlled trial assessing 6 months physical activity, diet and weight management interventions. The intervention group received motivational interviewing to encourage behavioural changes and showed a marginally significant increase in their metabolic equivalent (MET) minutes of moderate intensity physical activity and significantly improved fibre, fat and vegetable intake. The authors concluded that the use of a home based, low cost intervention using motivational interviewing, self monitoring and regular personal feedback can have a positive impact on behavioural changes to diet and physical activity levels in deprived areas with or at risk of metabolic syndrome
Abstract
BACKGROUND This study aimed to determine whether a home-based 6-month lifestyle intervention program complemented by motivational interviewing could improve diet and physical activity behaviours in 50-69 year olds with or at risk of metabolic syndrome, residing in a disadvantaged rural Western Australian community. METHODS Participants from the City of Albany and surrounding towns (n = 401) were recruited into a 6 month randomised controlled trial. They were screened for metabolic syndrome and randomly allocated to intervention (n = 201) or control group (n = 200). Baseline and post-test data collection for both groups included a self-report questionnaire which incorporated the Fat and Fibre Barometer and the International Physical Activity Questionnaire Short Form. The intervention group received the program materials at baseline and the control group was waitlisted. Generalised estimating equation models assessed repeated outcome measures over time. RESULTS A total of 151 (75.1%) intervention and 159 (79.5%) control group participants completed post-test and were included in the analysis. After controlling for confounders, the intervention group achieved a marginally significant increase in their metabolic equivalent (MET) minutes of moderate intensity physical activity per week (p = 0.049), and significantly improved fibre intake (p < 0.001), fat intake (p = 0.003), and vegetable serves per day (p = 0.002) from baseline to post-test relative to the control group. CONCLUSION A home-based, low-cost intervention with motivational support can effectively improve the physical activity and dietary behaviours of adults aged 50-69 years with or at risk of metabolic syndrome residing in a disadvantaged rural area. TRIAL REGISTRATION Anzctr.org.au Identifier: ACTRN12614000512628.
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Reversal of cognitive decline in Alzheimer's disease.
Bredesen, DE, Amos, EC, Canick, J, Ackerley, M, Raji, C, Fiala, M, Ahdidan, J
Aging. 2016;8(6):1250-8
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Alzheimer’s disease is the third leading cause of death and is one of the most significant global healthcare problems of modern times. It leads initially to cognitive decline – inability to recall words and faces, do mental calculations, navigate on familiar routes – and eventually to complete loss of memory and ability to perform routine daily tasks. Conventional therapy focuses on single drug therapies and success with these has been limited. This case study report details the results of 10 patients experiencing differing degrees of cognitive decline and early Alzheimer’s disease. Each patient followed a personalised, multiple therapy programme for 5 months to 2 years, based on their genetics, markers for blood glucose management, lipid profile, homocysteine, Vitamin D and inflammation, amongst others. Each case reports a quantified improvement in brain function, as well as subjective improvements reported by the carers and patients. The authors call for funding for a randomised controlled trial and for early detection and treatment using a multi-faceted protocol. Nutrition Practitioners working with cognitive decline can use the case study reports to inform their testing choices and personalised nutrition and lifestyle protocols.
Abstract
Alzheimer's disease is one of the most significant healthcare problems nationally and globally. Recently, the first description of the reversal of cognitive decline in patients with early Alzheimer's disease or its precursors, MCI (mild cognitive impairment) and SCI (subjective cognitive impairment), was published [1]. The therapeutic approach used was programmatic and personalized rather than monotherapeutic and invariant, and was dubbed metabolic enhancement for neurodegeneration (MEND). Patients who had had to discontinue work were able to return to work, and those struggling at work were able to improve their performance. The patients, their spouses, and their co-workers all reported clear improvements. Here we report the results from quantitative MRI and neuropsychological testing in ten patients with cognitive decline, nine ApoE4+ (five homozygous and four heterozygous) and one ApoE4-, who were treated with the MEND protocol for 5-24 months. The magnitude of the improvement is unprecedented, providing additional objective evidence that this programmatic approach to cognitive decline is highly effective. These results have far-reaching implications for the treatment of Alzheimer's disease, MCI, and SCI; for personalized programs that may enhance pharmaceutical efficacy; and for personal identification of ApoE genotype.
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Metabolic profiling distinguishes three subtypes of Alzheimer's disease.
Bredesen, DE
Aging. 2015;7(8):595-600
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The causes of Alzheimer’s Disease (AD) remain incompletely defined and there are currently no truly effective drug therapies available. However, there is growing evidence that disordered blood glucose management and hormonal changes and deficiencies, amongst other things, are implicated in symptom onset. Optimising these various metabolic processes, therefore, may be used as a comprehensive way to avoid cognitive decline or achieve cognitive improvements in symptomatic individuals. This report provides the metabolic results of 3 case studies and suggests 3 different types of AD classification, depending on the individual metabolic profile. Further studies are required to elaborate on the metabolic profiles suggested in this report, however Nutrition Practitioners working with cognitive decline, can use this report as a basis for individualised nutrition protocols to optimise metabolic processes in clients with cognitive decline.
Abstract
The cause of Alzheimer's disease is incompletely defined, and no truly effective therapy exists. However, multiple studies have implicated metabolic abnormalities such as insulin resistance, hormonal deficiencies, and hyperhomocysteinemia. Optimizing metabolic parameters in a comprehensive way has yielded cognitive improvement, both in symptomatic and asymptomatic individuals. Therefore, expanding the standard laboratory evaluation in patients with dementia may be revealing. Here I report that metabolic profiling reveals three Alzheimer's disease subtypes. The first is inflammatory, in which markers such as hs-CRP and globulin:albumin ratio are increased. The second type is non-inflammatory, in which these markers are not increased, but other metabolic abnormalities are present. The third type is a very distinctive clinical entity that affects relatively young individuals, extends beyond the typical Alzheimer's disease initial distribution to affect the cortex widely, is characterized by early non-amnestic features such as dyscalculia and aphasia, is often misdiagnosed or labeled atypical Alzheimer's disease, typically affects ApoE4-negative individuals, and is associated with striking zinc deficiency. Given the involvement of zinc in multiple Alzheimer's-related metabolic processes, such as insulin resistance, chronic inflammation, ADAM10 proteolytic activity, and hormonal signaling, this syndrome of Alzheimer's-plus with low zinc (APLZ) warrants further metabolic, genetic, and epigenetic characterization.